Specific glucagon-related peptides isolated from anglerfish islets are metabolic cleavage products of (pre)proglucagon-II

Proglucagons in vertebrates: Expression and processing of multiple genes in a bony fish

In contrast to mammals, where a single proglucagon (PG) gene encodes three peptides: glucagon, glucagon-like peptide 1 and glucagon-like peptide 2 (GLP-1; GLP-2), many non-mammalian vertebrates carry multiple PG genes. Here, we investigate proglucagon mRNA sequences, their tissue expression and processing in a diploid bony fish. Copper rockfish (Sebastes caurinus) express two independent genes coding for distinct proglucagon sequences (PG I, PG II), with PG II lacking the GLP-2 sequence. These genes are differentially transcribed in the endocrine pancreas, the brain, and the gastrointestinal tract. Alternative splicing identified in rockfish is only one part of this complex regulation of the PG transcripts: the system has the potential to produce two glucagons, four GLP-1s and a single GLP-2, or any combination of these peptides. Mass spectrometric analysis of partially purified PG-derived peptides in endocrine pancreas confirms translation of both PG transcripts and differential processing of the resulting peptides. The complex differential regulation of the two PG genes and their continued presence in this extant teleostean fish strongly suggests unique and, as yet largely unidentified, roles for the peptide products encoded in each gene.

Morphological basis of the interactions between endocrine cell types in the pancreatic islets of the teleost, Blennius gattoruggine

The endocrine pancreas of the teleost fish Blennius gattoruggine was studied by immunochemistry using both light and electron microscopy. Generally, one large Brockmann body, along with intermediate and small islets, was found. Cells immunoreactive (IR) to anti-insulin (B), anti-glucagon (A) anti-somatostatin (D) anti-pancreatic polypeptide and anti-PYY sera were detected with B cells located at the center of the islet and the other cell types forming a peripheral mantle. The B-cell cytoplasm showed rows of microtubules close to the secretory granules and perpendicular to the plasmalemma. The ultrathin section images revealed exocytotic and endocytotic features, and the presence of intercellular gap junctions between the plasmalemma of contiguous cells, suggesting intercellular routes of communication, e.g. via autocrine and/or paracrine mechanism. These features were observed in all of the cell types, and were abundant in D cells. D cells were particularly numerous in the islets and were disposed close to A and B cells, as observed in other teleost species. The most peripheral B cells, in closer contact with D cells than the central ones, appeared strongly immunolabeled, perhaps owing to the inhibitory action of somatostatin. Some D cells exhibited a long protrusion directed towards the center of the islet. In view of their cytological characteristics and their secretion, D cells might have an important role in the modulation of A and B-cell secretion in an endocrine and/or paracrine fashion.

Glucagon and glucagon-like peptides in fishes

Glucagon and glucagon-like peptides (GLPs) are coencoded in the vertebrate proglucagon gene. Large differences exist between fishes and other vertebrates in gene structure, peptide expression, peptide chemistry, and function of the hormones produced. Here we review selected aspects of glucagon and glucagon-like peptides in vertebrates with special focus on the contributions made by analysis of piscine systems. Our topics range from the history of discovery to gene structure and expression, through primary structures and regulation of plasma concentrations to physiological effects and message transduction. In fishes, the pancreas synthesizes glucagon and GLP-1, while the intestine may contribute oxyntomodulin, glucagon, GLP-1, and GLP-2. The pancreatic gene is short and lacks the sequence for GLP-2. GLP-1, which is produced exclusively in its biologically active form, is a potent metabolic hormone involved in regulation of liver glycogenolysis and gluconeogenesis. The responsiveness of isolated hepatocytes to glucagon is limited to high concentrations, while physiological concentrations of GLP-1 effectively regulate hepatic metabolism. Plasma concentrations of GLP-1 are higher than those of glucagon, and liver is identified as the major site of removal of both hormones from fish plasma. Ultimately, GLP-1 and glucagon exert effects on glucose metabolism that directly and indirectly oppose several key actions of insulin. Both glucagon and GLP-1 show very weak insulinotropic activity, if any, when tested on fish pancreas. Intracellular message transduction for glucagon, especially at slightly supraphysiological concentrations, involves cAMP and protein kinase A, while pathways for GLP are largely unknown and may involve a multitude of messengers, including cAMP. In spite of fundamental differences in GLP-1 function between fishes and mammals, fish GLP-1 is as powerful an insulinotropin for mammalian B-cells as mammalian GLP-1 is a metabolic hormone if tested on piscine liver.

Processing of mouse proglucagon by recombinant prohormone convertase 1 and immunopurified prohormone convertase 2 in vitro

The mouse tumor cell line alpha TC1-6 was used as a model system to examine the post-translational processing of proglucagon. Determination of the mouse preproglucagon cDNA sequence and comparison with the published sequences of rat and human preproglucagons revealed nucleic acid homologies of 89.1 and 84%, respectively, and amino acid homologies of 94 and 89.4%, respectively. Immunohistochemical analyses with antibodies directed against PC2 and glucagon colocalized both the enzyme and substrate within the same secretory granules. PC1 was also immunolocalized in secretory granules. Cells were metabolically labeled with [3H]tryptophan, and extracts were analyzed by reverse-phase high pressure liquid chromatography. Radioactive peptides with retention times identical to those of synthetic peptide standards were recovered and subjected to peptide mapping to verify their identities. To determine the potential role of PC1 and PC2 in proglucagon processing, 3H-labeled proglucagon was incubated in vitro with recombinant PC1 and/or immunopurified PC2. Both enzymes cleaved proglucagon to yield the major proglucagon fragment, glicentin, and oxyntomodulin, whereas only PC1 released glucagon-like peptide-I from the major proglucagon fragment. Neither PC1 nor PC2 processed glucagon from proglucagon in vitro. These results suggest a potential role for PC1 and/or PC2 in cleaving several of the normal products, excluding glucagon, from the mouse proglucagon precursor.

Distribution of peptidyl-glycine alpha-amidating monooxygenase immunoreactivity in the brain, pituitary and islet organ of the anglerfish (Lophius americanus)

Peptidyl-glycine alpha-amidating monooxygenase (PAM; EC 1.14.17.3) is an enzyme that catalyzes conversion of glycine-extended peptides to alpha-amidated bioactive peptides. Two peptides that are processed at their carboxyl-termini by this enzyme are neuropeptide Y and anglerfish peptide Y, both of which possess a C-terminal glycine that is used as a substrate for amidation. Results from previous reports have demonstrated that neuropeptide Y-like and anglerfish peptide Y-like immunoreactivities are present in the brain of anglerfish (Lophius americanus). Furthermore, neuropeptide Y-like peptides, namely anglerfish peptide Y and anglerfish peptide YG (the homologues of pancreatic polypeptide) are present in the islet organ of this species. Neuropeptide Y has also been localized in the anterior, intermediate and posterior lobes of the pituitary gland in a variety of species. In order to learn more about the distribution of the enzyme responsible for alpha amidation of these peptides in the brain and pituitary and to specifically investigate the relationship of this enzyme to peptide synthesizing endocrine cells of the anglerfish islet, we performed an immunohistochemical study using several antisera generated against different peptide sequences of the enzyme. PAM antisera labeled cells in the islet organ, pituitary and brain, and fibers in the brain and pituitary gland. The PAM staining pattern in the brain was remarkably similar to the distribution of neuropeptide Y immunoreactivity reported previously. Clusters of cells adjacent to vessels in the anterior pituitary displayed punctate PAM immunoreactivity while varicose fibers were observed in the pituitary stalk and neurohypophysis. Endocrine cells of the islet organ were differentially labeled with different PAM antisera. Comparison of the staining patterns of insulin, glucagon, and anglerfish peptide Y in the islet organ to PAM immunoreactivity suggests a distribution of forms of PAM enzyme in insulin and anglerfish peptide Y-containing cells, but no overlap with glucagon-producing cells. The results also indicate that PAM immunoreactivity is widely distributed in the brain, pituitary and islet organ of anglerfish in cells, that contain peptides that require presence of a C-terminal glycine for amidation.

Kinetic analyses of peptidylglycine alpha-amidating monooxygenase from pancreatic islets

Peptidylglycine alpha-amidating monooxygenase (PAM) plays an important role in the post-translational processing of bioactive neuropeptides by participating in C-terminal amidation. We have examined PAM activity in the pancreatic islets of the anglerfish (AF), Lophius americanus. It was previously demonstrated that the cofactor requirements and pH optimum for the fish PAM are essentially identical to PAM obtained from other tissues and species. The present study was performed to examine the enzymatic characteristics of the fish islet PAM in more detail. One of the questions addressed was the suitability of the AF islet neuropeptide Y-like peptide, aPY-Gly, as a substrate for the islet PAM. Partially purified PAM from AF islet secretory granules was incubated with [125I] aPY-Gly and the resulting products were analyzed by HPLC. The islet PAM readily mediated the formation of aPY-amide from aPY-Gly. PAM purified from bovine adrenal chromaffin granules also catalyzed the amidation of [125I] aPY-Gly. The kinetic parameters of the islet PAM were examined using trinitrophenylated-D-Tyr-Val-Gly (TNP-D-YVG) and 4-nitrohippuric acid (4-NHA). The Km of the islet PAM was 25 +/- 5 microM for TNP-D-YVG and 3.4 +/- 1 mM for 4-NHA. The competitive inhibitor of mammalian PAM activity, 4-methoxybenzoxyacetic acid, proved to be a potent inhibitor of the islet PAM as well, with an apparent KI of 0.06 mM. These results demonstrate that the AF islet PAM exhibits substrate compatibility, kinetic parameters, and inhibitor susceptibility quite similar to the characteristics of PAM from other tissues and species.

Pancreatic endocrine cells in sea bass (Dicentrarchus labrax L.) I. Immunocytochemical characterization of glucagon- and PP-related peptides

PP-, PYY-, and glucagon-immunoreactive cells were immunocytochemically identified in the pancreatic islets of Dicentrarchus labrax (sea bass). PYY cells also reacted with anti-PP serum. The specificity control showed that preabsorption of PP antiserum by PYY peptide abolished the immunostaining, while the reaction did not change when the PYY antiserum was preabsorbed by PP. These results suggested the existence of a PP/PYY molecule in the sea bass islets. The islet distribution of PP/PYY-immunoreactive cells differed markedly. Thus, in the principal islet and some intermediate islets few PP/PYY-immunoreactive cells are present (type I islets), whereas in the smaller and some intermediate ones they are numerous (type II islets). Adjacent sections stained by peroxidase-antiperoxidase (PAP) technique and individual sections stained by immunofluorescence double staining showed the coexistence of glucagon and PP/PYY-like immunoreactivities. Both islet types contained cells with PP/PYY coexisting with glucagon peptide, while cells showing solely glucagon immunoreactivity were found in type I islets only.

Metabolic actions of glucagon-family hormones in liver

This review addresses direct and indirect metabolic actions of hormones co-encoded in the preproglucagon gene of fishes. Emphasis is placed on a critical analysis of the effects of glucagon and glucagon-like peptide (GLP) and the current knowledge of the respective modes of action is reviewed. In mammals GLPs exert no direct metabolic actions. In fish liver, GLP and glucagon act on similar targets of intermediary metabolism by enhancing flux through glycogenolysis, lipolysis and gluconeogenesis. Increases in substrate oxidation are not uniform. Hormonal activation of glycogen phosphorylase and triglyceride lipase and inhibition of pyruvate kinase are implicated in these actions. Hormone-dependent hyperglycemia, depletion of hepatic glycogen and increases in free fatty acids are noticeablein vivo. Glucagon also activates hepatic amino acid uptake and ammonia excretion.Glucagon actions are accompanied by large increases in hepatic cAMP and increased phosphorylation of pyruvate kinase. Metabolic effects measured after GLP administration are associated with minor, if any, increases in cAMP and effects on pyruvate kinase are variable. We hypothesize that different hepatic receptors with differing modes of intracellular message transduction are involved in glucagon and GLP actions while targetting identical metabolic routes. Responses of different species of fish cover a wide spectrum, and variation of response with the circannual cycle of experimental animals makes comparisons of results, even within one species, difficult.

Metabolic effects of salmon glucagon and glucagon-like peptide in coho and chinook salmon

Different doses of glucagon and glucagon-like peptide (GLP) isolated from coho salmon, Oncorhynchus kisutch were tested in vivo and in vitro on juvenile coho and chinook (O. tshawytscha) salmon. Results obtained suggest an involvement of these peptides in the regulation of plasma glucose, plasma fatty acids, liver glycogen, and the hepatic enzymes: glycogen phosphorylase, pyruvate kinase, triacylglycerol lipase, and glucose-6-phosphate dehydrogenase. Metabolic effects were more enhanced in summer than either in spring or in autumn. GLP was less effective than glucagon in stimulating glycogenolysis in vivo. Salmon glucagon, especially in low concentrations, was generally more potent metabolically than mammalian (porcine/bovine) glucagon. The interaction between glucagon-family peptides and insulin seems to be different from the one described in mammals: glucagon and GLP either lowered plasma circulating levels of insulin or showed no effect. Only at the time of parr-smolt transformation did GLP slightly elevate plasma insulin levels in coho salmon.

Immunocytochemical and ultrastructural characterization of coexistence of pancreatic polypeptide and glucagon-like immunoreactivity in the pancreatic endocrine cells of Sparus auratus L. (Teleostei)

Coexistence of pancreatic polypeptide (PP)- and glucagon-like immunoreactivity was demonstrated in the pancreatic endocrine cells of the teleost fish Sparus auratus. An immunofluorescence double-staining method revealed coexistence of glucagon- and PP-like immunoreactivity in endocrine cells of small and intermediate islets. In contrast to small islets, the intermediate ones also contained a variable number of glucagon-immunoreactive cells next to cells having both immunoreactivities. Coexistence of both immunoreactivities could not be observed in endocrine cells of the principal islet, whereas many cells containing glucagon and a few cells containing PP immunoreactivity were found. By an immunogold double-staining method the precise ultrastructural location of each immunoreactivity could be demonstrated. Again, cells containing glucagon- and/or PP-like immunoreactivity were found. Although, only two different types of granules were observed, four distinct cell types could be distinguished. Based on this granule morphology two cell types showing coexistence were found: one cell type, only present in the small islets, showing a different distribution of glucagon and PP immunoreactivity within the granules (predominantly in the center and periphery, respectively) and another cell type with larger granule cores, present in small as well as intermediate islets, having a mixed distribution of both immunoreactivities.

Different cellular distributions of two somatostatins in brain and pancreas of salmonids, and their associations with insulin- and glucagon-secreting cells

Invariant somatostatin-14 (SST-14) and somatostatin-25 (SST-25), isolated from coho salmon pancreas (Plisetskaya et al., 1986a) are likely coded by two distinct somatostatin genes. The present study was undertaken to investigate whether these genes are expressed in the same or in different cell types in the pancreatic islets and in the brain of two salmonids: rainbow trout and coho salmon. Antibodies generated against SST-14, mammalian (m) SST-28(1-14), salmon (s) SST-25, salmon insulin, and salmon glucagon were used as immunocytochemical probes. Two distinct cell types containing SSTs were revealed in the pancreas of both salmonid species: one cell type immunoreactive to both SST-14 and mSST-28(1-14) and the other cell type immunoreactive only to sSST-25. The SST-14/mSST-28(1-14)-positive cells were limited to the more central parts of the islets, in apposition to the insulin-positive cells: sSST-25-positive cells were located more peripherally and were associated topographically with the glucagon-positive cells. In contrast to the pancreas, neurons in the neurohypophysis and hypothalamus of the rainbow trout and coho salmon contained only SST-14-like and mSST-28(1-14)-like immunoreactivities, while immunoreactivity to sSST-25 was completely absent. These results suggest that differentiation in the pancreas and brain of salmonid fishes results in cell types in which SST genes are separately expressed. The close topographical association of sSST-25 with glucagon cells, and of SST-14 with insulin cells, in the pancreatic islets implies yet unknown functional regulatory relationships that require detailed study.

Isolation of alligator gar (Lepisosteus spatula) glucagon, oxyntomodulin, and glucagon-like peptide: amino acid sequences of oxyntomodulin and glucagon-like peptide

Oxyntomodulin, glucagon, and a glucagon-like peptide (GLP) have been isolated from the endocrine pancreas of the alligator gar (Lepisosteus spatula), a ganoid fish. The three peptides were isolated by gel filtration and HPLC and were identified by size, composition, and glucagon-like immunoreactivity. The amino acid sequences of the oxyntomodulin and GLP were determined. The oxyntomodulin contains 36 amino acid residues and its sequence is H S Q G T F T N D Y S K Y L D T R R A Q D F V Q W L M S T K R S G G I T. The composition of the glucagon is identical to the N-terminal 29 residues of the gar oxyntomodulin. The single form of GLP found contains 34 amino acid residues in the following sequence: H A D G T Y T S D V S S Y L Q D Q A A K K F V T W L K Q G Q D R R E. These findings suggest that all three peptides are derived from a common precursor.

Peptidyl-glycine alpha-amidating monooxygenase is present in islet secretory granules of the anglerfish, Lophius americanus

Anglerfish islet secretory granules have been examined for the presence of an enzyme which could perform C-terminal amidation of glucagon-like peptide II and possibly anglerfish peptide Y. Using [125I]D-Tyr-Val-Gly as substrate, a peptidyl-glycine alpha-amidating monooxygenase (PAM) was detected in islet secretory granule lysates. The enzyme is active between pH 6.0 and 8.5 and exhibits maximal activity near pH 7.0. The islet PAM requires Cu2+, ascorbate, and molecular oxygen for activity. Other divalent metal ions and redox cofactors were tested and found to be inactive in the assay. Even though added Cu2+ and ascorbate are required for detecting islet PAM activity, when these factors were incubated with substrate in the absence of secretory granule lysate, no activity was observed. It was also found that the addition of higher than optimal concentrations of either Cu2+ or ascorbate inhibited amidating activity. The results demonstrate that a PAM is present in secretory granules of anglerfish islet tissue. The characteristics of the islet PAM are similar to those of PAMs identified and characterized in other tissues which produce bioactive C-terminally amidated peptides.

Glucagon-like peptides activate hepatic gluconeogenesis

Piscine (anglerfish, catfish, coho salmon) glucagon-like peptides (GLPs), applied at 3.5 nM, stimulate (1.1-1.9-fold) flux through gluconeogenesis above control levels in isolated trout and salmon hepatocytes. Human GLP-1 and GLP-2 also activate gluconeogenesis, but to a lesser degree than their piscine counterparts. Minor increases of substrate oxidation are noticed at times of peak gluconeogenic activation through GLPs. These hormones, which are derived from the same precursor peptide as glucagon are more potent activators of gluconeogenesis than glucagon when applied at equimolar concentrations, and do not appear to employ cAMP or cGMP as the intracellular messenger in hepatic tissue.

Oxytocin-like immunoreactive nerves are associated with insulin-containing cells in pancreatic islets of anglerfish (Lophius americanus)

Recent reports indicate that oxytocin exerts direct effects on the release of insulin and glucagon from the endocrine pancreas of the rat. The purpose of this study was to determine whether oxytocin-like immunoreactivity is present in the anglerfish islet, and if it is associated with subsets of hormone-producing cells. Antisera against oxytocin, insulin, glucagon, somatostatin, neuropeptide Y, and the 200-kd neurofilament polypeptide were applied to serial 5 micrometers sections of pancreatic islets. The antiserum to the 200-kd neurofilament polypeptide labeled nerve bundles and axons, some of which were also stained with the oxytocin antiserum. Oxytocin immunoreactivity was observed in large nerves that branched into varicose fibers. These fibers were consistently associated only with clusters of insulin-producing cells. Successive application of oxytocin and insulin antisera to the same section provided additional verification of this relationship. Oxytocin-labeled nerves were not associated with cells immunoreactive to glucagon, somatostatin, or neuropeptide Y (anglerfish peptide Yg). The results demonstrate that oxytocin or an oxytocin-like peptide is located in fibers that surround only insulin-producing cells in the anglerfish islet. Although the functional significance of this observation remains to be determined, the results imply that oxytocin, or an oxytocin-like peptide, may affect the synthesis or release of insulin from anglerfish islets.

Anglerfish islets contain NPY immunoreactive nerves and produce the NPY analog aPY

It has recently been demonstrated that aPY, a peptide which has significant homology with neuropeptide Y (NPY) is present in extracts of anglerfish islets. The purpose of this study was to determine whether cells or nerves which contain NPY-like immunoreactivity could be identified in anglerfish islet tissue and whether aPY is synthesized by this tissue. Antisera against bovine pancreatic polypeptide (BPP), NPY and the 200 kd neurofilament polypeptide were used for immunohistochemical analysis of islets. Identical cells were stained by both the NPY and BPP antisera. The NPY and 200 kd neurofilament antisera also labeled nerve fibers in the tissue which were not stained with the BPP antiserum. The nature of the NPY-like peptide synthesized in islet cells was determined by subjecting differentially radioactively labeled Mr 2,500-8,000 peptides from islet extracts to reverse phase HPLC. Labeled aPY was unequivocally identified in the extracts and was labeled appropriately (as predicted from its sequence) with 13 different radioactive amino acids. These results demonstrate that one form of NPY-like peptide synthesized in anglerfish islets is aPY. The form of NPY-like peptide which was immunolocalized in nerves remains to be determined.